DE60106476T2 - METHOD AND DEVICE FOR DETERMINING THE MAIN PARAMETER VALUES OF A STORAGE MEDIUM REQUIRED FOR PLAYING THE STORAGE MEDIUM - Google Patents

Description

The The invention relates to a method and a device for determination of main parameter values of a storage medium used to play back the Storage medium needed , wherein the storage medium has a first data area in which the Main parameter values be stored and a second data area that is not the Parameter values but contains other data.

background

A DVD disk contains a small lead-in area, the sync sectors, control data with the number of recording surfaces, Plate key and contains other information, and the plate contains a data area that consumes the bulk of the available disk space takes. To the contents of a DVD video disc to handle must be a logical sector number designated LSN transformed into a physical sector number designated PSN become. A DVD disc can contain up to four recording areas.

If be accessed to more than one recording surface US-A-5,966,721 discloses how to control the contents of the run-in areas of several recording surfaces of only one area make it readable. EP-A-0 834 876 describes a method for Discriminating the type of a DVD (i.e., number of areas) the sync signal.

invention

The to be solved by the invention Task is to set important data parameters in the lead-in area the disk are stored, and that are needed to play the disk, from other data coming from the non-enema area of the Be read without the required data parameters from the disk Inlet area to read. This task is by the in the claim 1 disclosed method solved. An apparatus using this method is in the claim 9 discloses.

According to the invention becomes the contents of the disk data area used to provide the necessary information for a transformation between LSN and PSN numbers without reading information from an entry area - below labeled Lead In - too determine.

• – charakteristische Dateisystem-Daten am Beginn von Schicht 0;
• – spezifische DVD-Videodaten, die sich am Beginn von Schicht 0 befinden;
• – Sektor IDs;
• – wenn Schicht 1 vorhanden ist, spezifische DVD-Videodaten, die sich am inneren Radius von Schicht 1 befinden;
• – wenn Platte mit entgegengesetztem Spurweg vorhanden ist, die Struktur von spezifischen DVD-Videodaten, die sich am äußeren Radius der Schichten 0 und 1 befinden.

The following data range data is used to determine the important or main parameters:

• Characteristic file system data at the beginning of shift 0 ;
• - specific DVD-Video data, which is at the beginning of shift 0 are located;
• - sector IDs;
• - if shift 1 is present, specific DVD-video data, which is at the inner radius of layer 1 are located;
• If there is a plate with opposite track path, the structure of specific DVD-Video data, which is at the outer radius of the layers 0 and 1 are located.

Without a look into the inlet area determines the proposed method the location of the lead-in area, the lead-out area, the data area, of the mid-range (if any), and it determines the type of DVD disc.

• – Platten_Typ (einzelne Schicht, paralleler Spurweg oder entgegengesetzter Spurweg);
• – Start_PSN_Schicht_0 (Bereich: 0 ... FFFFFF_h);
• – End_PSN_Schicht_0 (Bereich: 0 ... FFFFFF_h);
• – Start_PSN_Schicht_1 (Bereich: 1000000_h ... 1FFFFFF_h);
• – End_PSN_Schicht_1 (Bereich: 1000000_h ... 1FFFFFF_h).

The invention automatically allows the determination of the following variables, which are referred to in this application as the main variable:

• Plate_type (single layer, parallel track, or opposite track);
• - Start_PSN_Layer_0 (Range: 0 ... FFFFFF _h );
• - End_PSN_Layer_0 (range: 0 ... FFFFFF _h );
• - Start_PSN_Layer_1 (Range: 1000000 _h ... 1FFFFFF _h );
• - End_PSN_Layer_1 (range: 1000000 _h ... 1FFFFFF _h ).

The last four of those five Variables represent a complete one Replacement for the information from the data area allocation field (BP 4 to 15) represents what in the DVD specification for Read Only Disks, Part 1, Version 1.0, 3.4.1.3.1 Physical Format Information, is described.

in the Principle is the inventive method suitable for the determination of at least one main parameter value of a storage medium, the is needed to play the storage medium, the storage medium a first data area in which the at least one main parameter word is stored, and a second data area that is not the at least one main parameter value, but includes other data includes, and wherein the at least one main parameter value is read and evaluated by Data from the second area is determined without the least a main parameter value is read from the first data area.

• – Mittel zum Antreiben der Datenplatte;
• – eine Abtastanordnung zum Lesen von Daten von der Datenplatte;
• – einen Puffer;
• – Mittel zum Steuern der Antriebsmittel, des Abtasters und des Puffers und zur Bestimmung des wenigstens einen Haupt-Parameterwertes durch Lesen und Bewerten von Daten aus dem zweiten Datenbereich, ohne den wenigstens einen Haupt-Parameterwert aus dem ersten Datenbereich zu lesen.

In principle, the device according to the invention is suitable for determining at least one main parameter value of a data disk required for playing the data disk, the data disk having a first data area in which the at least one main parameter value is stored, and a second data area, which does not include the at least one main parameter value but other data, the Device includes:

• - means for driving the data disk;
• A scanning device for reading data from the data disk;
• A buffer;
• - means for controlling the drive means, the scanner and the buffer and for determining the at least one main parameter value by reading and evaluating data from the second data area without reading the at least one main parameter value from the first data area.

advantageous additional embodiments The invention are disclosed in the corresponding subclaims.

drawings

embodiments the invention will be described with reference to the accompanying drawings, they show:

1 the transformation of LSN into PSN numbers;

2 the transformation from PSN to LSN numbers;

3 a method for searching the main variables;

4 basic steps for fast searching;

5 Function: Find the plate type;

6 Function: fast searching for major variables;

7 Function: Find the last LSN about subdivision size;

8th Function: Find the main variable for single-layer disk;

9 Function: Find the main variable for parallel track plate;

10 Function: Find the main variables for opposite track plate;

11 simplified block diagram of a DVD player.

embodiments

The mentioned above Main variables and the way to their calculation or determination will now be in greater detail based on clauses of the DVD specification for read-only disc, Part 1, Version 1.0, described.

• – Platten_Typ = einzelne Schicht
• – Start_PSN_Schicht_0 = „Start-Sektor-Nummer des Datenbereichs" in Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – End_PSN_Schicht_0 = „End-Sektor-Nummer des Datenbereichs" in Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – Start_PSN_Schicht_1 ist nicht vorhanden.
• – End_PSN_Schicht_1 ist nicht vorhanden.

For single-layer DVD discs:

• - plates_type = single layer
• - Start_PSN_Schicht_0 = "Start Sector Number of the Data Area" in Lead In as described in 3.4.1.3.1 Physical Format Information (BP 4 to 15) Data Assignment.
• - End_PSN_Schicht_0 = "End sector number of the data area" in Lead In as described in 3.4.1.3.1 Physical format information (BP 4 to 15) Data assignment.
• - Start_PSN_Schicht_1 does not exist.
• - End_PSN_Schicht_1 does not exist.

• – Platten_Typ = paralleler Spurweg
• – Start_PSN_Schicht_0 = „Start-Sektor-Nummer des Datenbereichs" in der Schicht 0 Lead In wie beschrieben in 3.4.1.3.1. Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – End_PSN_Schicht_0 = „End-Sektor-Nummer des Datenbereichs" in der Schicht 0 Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – Start_PSN_Schicht_1 = 1000000_h + „Start-Sektor-Nummer des Datenbereichs" in der Schicht 1 Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – End_PSN_Schicht_1 = 1000000_h + „End-Sektor-Nummer des Datenbereichs" in der Schicht 1 Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.

For DVD tracks with parallel track path, which have two layers:

• Plate_type = parallel track path
• - Start_PSN_Schicht_0 = "Start sector number of the data area" in the layer 0 Lead In as described in 3.4.1.3.1. Physical Format Information (BP 4 to 15) Data Mapping.
• - End_PSN_Layer_0 = "End sector number of the data area" in the layer 0 Lead In as described in 3.4.1.3.1 Physical Format Information (BP 4 to 15) Data Mapping.
• - Start_PSN_Layer_1 = 1000000 _h + "Start sector number of the data area" in the shift 1 Lead In as described in 3.4.1.3.1 Physical Format Information (BP 4 to 15) Data Mapping.
• - End_PSN_Layer_1 = 1000000 _h + "End sector number of the data area" in the layer 1 Lead In as described in 3.4.1.3.1 Physical Format Information (BP 4 to 15) Data Mapping.

• – Start_PSN_Schicht_0 = „Start-Sektor-Nummer des Datenbereichs" in Lead In wie beschrieben in 3.4.1.3.1 Physikalische Forma-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – End_PSN_Schicht_0 = „End-Sektor-Nummer in Schicht 0" in Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.
• – Start_PSN_Schicht_1 = 1FFFFFF_h – End_PSN_Schicht_0, d. h. die Sektor-Nummer Start_PSN_Schicht_1 folgt unmittelbar der Sektor-Nummer End_PSN_Schicht_0.
• – End_PSN_Schicht_1 = 1000000_h + „End-Sektor-Nummer des Datenbereiches" in Lead In wie beschrieben in 3.4.1.3.1 Physikalische Format-Informationen (BP 4 bis 15) Daten-Zuordnung.

For DVD tracks with opposite track path, which have two layers:
Plate_type = opposite lane path

• - Start_PSN_Schicht_0 = "Start Sector Number of the Data Area" in Lead In as described in 3.4.1.3.1 Physical Forma Information (BP 4 to 15) Data Assignment.
• - End_PSN_Schicht_0 = "End sector number in shift 0 in Lead In as described in 3.4.1.3.1 Physical Format Information (BP 4 to 15) Data Mapping.
• Start_PSN_Schicht_1 = 1FFFFFF _h - End_PSN_Schicht_0, ie the sector number Start_PSN_Schicht_1 follows immediately the sector number End_PSN_Schicht_0.
• - End_PSN_Layer_1 = 1000000 _h + "End sector number of the data area" in Lead In as described in 3.4.1.3.1 Physical format information (BP 4 to 15) Data assignment.

• – PSN = „Physikalische Sektor-Nummer", Wortlänge 25 Bits, Bereich für Schicht 0: 0 ... 0FFFFFF_h Bereich für Schicht 1: 1000000_h ... 1FFFFFF_h PSN ist identisch mit den 25 Bits geringster Wertigkeit von ID.
• – ID = „Identifikationsdaten" wie beschrieben in 3.2.2 Identifikationsdaten, d. h. ein ID besteht aus Sektor-Informationen und einer physikalischen Sektor-Nummer PSN.

The variables PSN and ID are as follows Are defined:

• - PSN = "Physical sector number", word length 25 bits, area by layer 0 : 0 ... 0FFFFFF _h area by layer 1 : 1000000 _h ... 1FFFFFF _h PSN is identical to the 25 least significant bits of ID.
• ID = "identification data" as described in 3.2.2 Identification data, ie an ID consists of sector information and a physical sector number PSN.

The two layers of the storage medium can be different on Pages of a disk are located, or they may be on one side of a multi-layered storage medium which can also be two-sided. It is also possible that the plate has a single layer on one side and two layers on the other hand has.

In In the figures, Y ', yes',' n ', no', 'NV_PCK', navigation pack ',' LSB ', least significant bit'.

• 1: Start
• 2: LSN ≤ (Emd_PSN_Schicht_0 – Start_PSN_Schicht_0) ?
• 3: Bereichstyp von ID ist Datenbereich PSN = LSN + Start_PSN_Schicht_0
• 4: Bereichstyp von ID ist Datenbereich PSN = LSN + Start_PSN_Schicht_1 + Start_PSN_Schicht_0 – End_PSN_Schicht_0 – 1
• 5: Ende

The transformation from the logical sector number LSN to the physical sector number PSN is in connection with 1 described.

• 1: Start
• 2: LSN ≤ (Emd_PSN_Schicht_0 - Start_PSN_Schicht_0)?
• 3: Range type of ID is data range PSN = LSN + Start_PSN_Layer_0
• 4: Range type of ID is data range PSN = LSN + Start_PSN_Schicht_1 + Start_PSN_Schicht_0 - End_PSN_Schicht_0 - 1
• 5: end

It gives no error handling, d. H. LSN must be within the range lying, which is provided by the existing data area of the disk.

• 6: Start
• 7: ist das Bit höchster Wertigkeit (das 25ste Bit) von PSN null, d. h. ist die Schicht 0 vorhanden?
• 8: LSN = PSN – Start_PSN_Schicht_0
• 9: LSN = PSN – Start_PSN_Schicht_1 – Start_PSN_Schicht_0 + End_PSN_Schicht_0 + 1
• 10: Ende

The transformation from a PSN number to an LSN number will be in conjunction with 2 described.

• 6: Start
• 7: is the highest order bit (the 25th bit) of PSN zero, that is, the layer 0 available?
• 8th: LSN = PSN - Start_PSN_Layer_0
• 9: LSN = PSN - Start_PSN_Schicht_1 - Start_PSN_Schicht_0 + End_PSN_Schicht_0 + 1
• 10: end

It gives no error handling, d. H. PSN must be in the existing data area show the plate.

• 11: Start
• 12: Platte eingeführt ?
• 13: primärer Lautstärke-Deskriptor PVD = 30010_h Annahme, dass es eine DVD ist => versuche Sektor PSN = i zu lesen.
• 14: Sektor PSN = pvd gefunden ?
• 15: Platte ist entweder beschädigt oder nicht vom DVD-ROM-Typ
• 16: Zeigt an, dass die ID von Sektor PSN = pvd ein Datenbereichs-Sektor ist (Bereichs-Typ von ID = Datenbereich) ?
• 17: pvd = 31010_h
• 18: zeigt an, dass die ID von Sektor PSN = pvd ein Datenbereichs-Sektor ist (Bereichs-Typ von ID = Datenbereich) ?
• 19: Es ist keine DVD-Videoplatte
• 20: es ist eine DVD-RAM-Platte: Platten_Typ = einzelne Schicht; Start_PSN_Schicht_0 = 31000_h
• 21: Für DVD-ROM, DVD-R, DVD – RW und DVD + RW: Start_PSN_Schicht_0 = 30000_h; Unter der Annahme, dass es eine DVD-Platte mit dualer Schicht ist => verwende die Position des optischen Kopfes oder des Abtasters auf demselben Radius, der zum Lesen des Sektors 30010_h der Schicht 0 verwendet wurde, um einen Sektor von Schicht 1 zu lesen.
• 22: irgendeinen Sektor gefunden ?
• 23: Platten_Typ = einzelne Schicht
• 24: Platten_Typ = duale Schicht (vorübergehender Zustand)
• 25: versuche schnelle Verarbeitungsschritte
• 26: sind alle Arten von Haupt-Variablen vollständig bekannt?
• 27: Springe zum äußeren Radius der Platte, beachte die unterschiedlichen Radien: 8 cm und 12 cm; lies aufeinanderfolgende Sektoren von Schicht 0, um die Grenze zwischen Datenbereich und Auslaufbereich oder Mittelbereich zu lokalisieren; End_PSN_Schicht_0 = PSN des letzten Datenbereich-Sektors.
• 28: Gibt es einen Auslaufbereich in Schicht 0 am äußeren Radius der Platte ?
• 29: Ist Platten_Typ = duale Schicht ?
• 30: Platten_Typ = paralleler Spurweg Start_PSN_Schicht_1 = 1030000_h;
• 31: wechsle zu Schicht 1; lies aufeinanderfolgende Sektoren von Schicht 1, um die Grenze zwischen dem Datenbereich und dem Auslaufbereich zu lokalisieren; End_PSN_Schicht_1 = PSN des letzten Datenbereich-Sektors
• 32: Platten_Typ = entgegengesetzter Spurweg; Start_PSN_Schicht_1 = 1FFFFFFh – End_PSN_Schicht_0;
• 33: springe zum inneren Radius der Platte in Schicht 1 beim Radius von Sektor PSN = 30000_h; lies aufeinanderfolgende Sektoren von Schicht 1, um die Grenze zwischen Datenbereich und Auslaufbereich zu lokalisieren; End_PSN_Schicht_1 = PSN des letzten Datenbereich-Sektors
• 34: Ende

The method for searching the main variables is used in conjunction with 3 described. The main variables are found in each case. A disadvantage of this method is that a large-pitch jump of the optical head between the inner and outer radius of the disk is required. Such jumps require a few seconds. Advantageously, step allows 16 first try other steps that work faster. Only if the faster steps fail, the slow, but in any case working, processing is performed. However, tests have shown that the fast version of the processing steps finds the right main variables for almost all existing DVD video discs.

• 11: Start
• 12: Plate inserted?
• 13: primary volume descriptor PVD = 30010 _h Assuming it is a DVD => try to read sector PSN = i.
• 14: Sector PSN = pvd found?
• 15: Disk is either damaged or not of the DVD-ROM type
• 16: Indicates that the ID of sector PSN = pvd is a data area sector (area type of ID = data area)?
• 17: pvd = 31010 _h
• 18: indicates that the ID of sector PSN = pvd is a data area sector (area type of ID = data area)?
• 19: It's not a DVD video disc
• 20: it is a DVD-RAM disk: disk_type = single layer; Start_PSN_Layer_0 = 31000 _h
• 21: For DVD-ROM, DVD-R, DVD-RW and DVD + RW: Start_PSN_Layer_0 = 30000 _h ; Assuming that there is a DVD disk with a dual layer => the position of the optical head or the scanner used at the same radius, the _h for reading the sector of the layer 30010 0 was used to layer a sector of 1 to read.
• 22: found any sector?
• 23: plate_type = single layer
• 24: plate_type = dual layer (transient state)
• 25: try fast processing steps
• 26: Are all types of main variables fully known?
• 27: Jump to the outer radius of the plate, be Pay attention to the different radii: 8 cm and 12 cm; read successive sectors of shift 0 to locate the boundary between the data area and the spill area or middle area; End_PSN_Layer_0 = PSN of the last data area sector.
• 28: Is there an exit area in shift 0 on the outer radius of the plate?
• 29: Is plate_type = dual layer?
• 30: plate_type = parallel lane start_PSN_layer_1 = 1030000 _h ;
• 31: change to shift 1 ; read successive sectors of shift 1 to locate the boundary between the data area and the exit area; End_PSN_Layer_1 = PSN of the last data area sector
• 32: plate_type = opposite lane path; Start_PSN_Layer_1 = 1FFFFFF H - End_PSN_Layer_0;
• 33: Jump to the inner radius of the plate in layer 1 at radius of sector PSN = 30000 _h ; read successive sectors of shift 1 to locate the boundary between the data area and the exit area; End_PSN_Layer_1 = PSN of the last data area sector
• 34: end

Fast processing steps to search the main variables

• 50: Start
• 51: Finde den Platten_Typ
• 52: Schnelle Suche nach den Haupt-Variablen
• 53: Ende

This type of processing is in 4 shown.

• 50: Start
• 51: Find the plate_type
• 52: Quick search for the main variables
• 53: end

• 60: Start
• 61: Ist Platten_Typ = einzelne Schicht ?
• 62: Unter der Annahme einer DVD-Platte mit parallelem Spurweg => verwende die Abtaster-Position auf demselben Radius, der zum Lesen des Sektors 30010_h von Schicht 0 verwendet wurde, um einen Sektor von Schicht 1 zu lesen.
• 63: Ist Sektor PSN nennenswert größer als 1030010_h ?
• 64: Platten_Typ = entgegengesetzter Spurweg
• 65: Platten_Typ = paralleler Spurweg Start_PSN_Schicht_1 = 1030000_h
• 66: Ende

step 51 from 4 is referred to as "find plate type" and contains the others in 5 illustrated steps.

• 60: Start
• 61: Is plate_type = single layer?
• 62: Assuming a DVD Parallel Track Path disc => the pickup position used on the same radius, the _hour for reading the sector from 30,010 layer 0 was used to layer a sector of 1 to read.
• 63: Is sector PSN appreciably larger than 1030010 _h ?
• 64: plate_type = opposite lane path
• 65: plate_type = parallel lane start_PSN_layer_1 = 1030000 _h
• 66: end

These Processing can also be described as follows:

Of the Parameter_plate_type can be read by reading at least one PSN at the beginning the first plate layer and at least one PSN on the same or a similar one Radial location in the other plate layer can be determined. If the difference between the corresponding PSN numbers of the two Layers considerably is, it must be a plate with opposite track way. If the difference is small, it is a plate with parallel track path.

If on the other hand, at the radial location of Lead In the first layer corresponding lead in is present in the other layer it would be a plate with a parallel track path. If at the radial location Lead In the first shift, a corresponding Lead Out in the other layer exists, it must have a plate with opposite Be track way. It is not necessary to change the content of the Lead In to read. One knows, that the sector ID is sufficient because the sector ID determines whether it's a Lead In or a Lead Out or a Data range.

• 80: Start
• 81: Ist Platten_Typ = eine Schicht ?
• 82: Ist Platten_Typ = paralleler Spurweg ?
• 83: Finde die Haupt-Variablen für die Platte mit einer Schicht.
• 84: Finde die Haupt-Variablen für die Platte mit parallelem Spurweg.
• 85: Finde die Haupt-Variablen für die Platte mit entgegengesetztem Spurweg.
• 86: Ende

As a further alternative, it is assumed that one of the possible dual-layer disk types is genuine, and the decoding of the payload data (e.g., video data or audio data) stored on the disk is started. If errors or inconsistencies occur during decoding, it is assumed that a disk type with a page is true and the decoding is retried. Whether it is a parallel track or opposite track path plate may be determined by assuming the presence of one of these types, followed by a request for a jump to another sector number (ie, a jump in a particular radial direction), and by checking the correct decoding processing. step 52 from 4 has the function name "fast search for the main variables" and contains the others in 6 illustrated steps.

• 80: Start
• 81: Is plate_type = one layer?
• 82: Is plate_type = parallel lane?
• 83: Find the main variables for the plate with a layer.
• 84: Find the main variables for the parallel track plate.
• 85: Find the main variables for the opposite lane disc.
• 86: end

• 100: Start
• 101: Untersuchung des Dateisystems UDF/ISO9660 (Universelles Plattenformat): finde das Partitionsende. pvd: letzte_LSN = Raumvolumengröße Partitions-Deskriptor: letzte_LSN = Partitions-Startort + Partitionslänge
• 102: wähle den höheren letzten LSN-Wert aus beiden Dateisystemen.
• 103: Setze die 8 LSBs der ausgewählten letzten LSN auf ,1!.
• 104: Ende

In conjunction with some of the following figures, some processing steps with the function name "find last LSN over partition size" are required 7 shown.

• 100: Start
• 101: Examination of file system UDF / ISO9660 (universal disk format): find the partition end. pvd: Last_LSN = Room Volume Size Partition Descriptor: Last_LSN = partition start location + partition length
• 102: choose the higher last LSN value from both file systems.
• 103: Set the 8 LSBs of the selected last LSN, 1 !.
• 104: end

• 150: Start
• 151: führe die Funktion aus „finde letzte LSN über Partitionsgröße".
• 152: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + letzte_LSNBemerkung: End_PSN_Schicht_0 kann niedriger sein als die PSN des letzten logischen Sektors dieser Platte, aber der gefundene Wert ist genau genug für ein vollständiges Abspielen der Platte ohne irgendwelche Beschränkungen für einen Benutzer.
• 153: Ende

step 83 from 6 has the function label "find the main variables for the single-layer disk" and close the others in 8th a step shown.

• 150: Start
• 151: execute the function "find last LSN about partition size".
• 152: End_PSN_Layer_0 = Start_PSN_Layer_0 + Last_LSN Note: End_PSN_Layer_0 may be lower than the PSN of the last logical sector of this disk, but the value found is accurate enough for a complete playback of the disk without any restrictions on a user.
• 153: end

• 200: Start
• 201: führe die Funktion aus „finde letzte LSN über Partitionsgröße".
• 202: Starte mit dem Lesen von Sektoren von PSN = 1030000_h.
• 203: Ist einer der gelesenen Sektoren ein NV_PCK ?
• 204: Speichere IV_PCK_LBN von diesem NV_PCK in einer Variablen nv_lbn; speichere PSN von diesem NV_PCK in Variabler nv_psn.
• 205: Wechsle in das DVD-Videotitel-Gruppenverzeichnis VIDEO_TS; untersuche die Stromdateien VTS_xx_yy.VOB, worin xx von 1 bis 99 und yy von 1 bis 9 läuft; suche nach einer VTS_xx_yy.VOB-Datei, die nicht die letzte Datei eines Videotitels ist und deren Größe kleiner ist als 2²⁰ – 2048 Bytes (wenn eine solche Datei existiert), und die nahe dem Sektor LSN = letzte_LSN/2 endet.
• 206: Gibt es eine solche Datei ?
• 207: End_PSN_Schicht_0 = (Start_PSN_Schicht_0 + letzte LSN) jener VTS_xx_yy.VOB-Datei; setze die 8 LSBs der End_PSN_Schicht_0 auf ,1'; End_PSN_Schicht_1 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + letzte_LSN-End_PSN_Schicht_0 – 1;
• 208: ist von der zugeordneten VTS_xx_1.VOB die Start-LSN + nv_lbn + Start_PSN_Schicht_0 + Start_PSN_Schicht_1 – End_PSN_Schicht_0 – 1 nahe oder gleich nv_psn ?
• 209: Finde die Start_LSN der Datei VTS_xx_yy.VOB (xx: 1 bis 99; yy: 0 oder 1) für die min (|((letzte_LSN + 1)/2) – nv_lbn – (Start_LSN von VTS_xx_yy.VOB)|) wahr ist und speichere diese Start-LSN in einer Variablen vob_lsn.
• 210: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + vob_lsn + nv_lbn – nv_psn – 1; End_PSN_Schicht_1 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + letzte_LSN – End_PSN_Schicht_0 – 1;
• 211: lies die Videotitel-Gruppen-Informations-Management-Tabelle VTSI_MAT der Titel-Informationsdatei VTS_xx_0.IFO und der Sicherungs-Titel-Informationsdatei VTS_xx_0.BUP (die .BOP-Datei ist Byte-identisch mit der .IFO-Datei), die sich in der Schicht 0 gerade vor der ersten und in der Schicht 1 gerade hinter der letzten „.VOB"-Datei von diesem Titel befinden muss.
• 212: Sind beide VTSI_MATs gleich ?
• 213: End_PSN_Schicht_0 und End_PSN_Schicht_1 sind richtig.
• 214: End_PSN_Schicht_0 und End_PSN_Schicht_1 sind falsch.
• 215: Gibt es eine andere Datei VTS_xx_yy.VOB, in der xx von 1 bis 99 und yy von 1 bis 9 läuft, die nicht die letzte Datei eines Videotitels ist, und deren Größe kleiner als 2²⁰ – 2048 Bytes ist (wenn irgendeine solche Datei vorhanden ist), und die dicht bei dem Sektor LSN = letzte_LSN/2 endet ?
• 216: Ende.

step 84 from 6 has the function name "find the main variables for the disk with parallel track path" and contains the others in 9 illustrated steps.

• 200: Start
• 201: execute the function "find last LSN about partition size".
• 202: Start reading sectors from PSN = 1030000 _h .
• 203: Is one of the sectors read an NV_PCK?
• 204: Store IV_PCK_LBN from this NV_PCK in a variable nv_lbn; save PSN from this NV_PCK in variable nv_psn.
• 205: Change to the DVD Video Title group directory VIDEO_TS; examine the stream files VTS_xx_yy.VOB, where xx runs from 1 to 99 and yy from 1 to 9; search for a VTS_xx_yy.VOB file that is not the last file of a video title and whose size is less than 2 ²⁰ - 2048 bytes (if such a file exists), and which ends near sector LSN = last_LSN / 2.
• 206: Is there such a file?
• 207: End_PSN_Layer_0 = (Start_PSN_Layer_0 + Last LSN) of that VTS_xx_yy.VOB file; set the 8 LSBs of End_PSN_Layer_0, 1 '; End_PSN_Schicht_1 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Last_LSN-End_PSN_Schicht_0 - 1;
• 208: is the start LSN + nv_lbn + start_PSN_layer_0 + start_PSN_layer_1 - end_PSN_layer_0 - 1 close or equal to nv_psn from the assigned VTS_xx_1.VOB?
• 209: Find the Start_LSN of the file VTS_xx_yy.VOB (xx: 1 to 99; yy: 0 or 1) for the min (| ((last_LSN + 1) / 2) - nv_lbn - (Start_LSN of VTS_xx_yy.VOB) |) is and store these start LSNs in a variable vob_lsn.
• 210: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + vob_lsn + nv_lbn - nv_psn - 1; End_PSN_Schicht_1 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Last_LSN - End_PSN_Schicht_0 - 1;
• 211: Read the video title group information management table VTSI_MAT of the title information file VTS_xx_0.IFO and the backup title information file VTS_xx_0.BUP (the .BOP file is byte identical to the .IFO file) yourself in the shift 0 just before the first and in the shift 1 just past the last ".VOB" file from this title.
• 212: Are both VTSI_MATs the same?
• 213: End_PSN_Layer_0 and End_PSN_Layer_1 are correct.
• 214: End_PSN_Layer_0 and End_PSN_Layer_1 are incorrect.
• 215: Is there another VTS_xx_yy.VOB file in which xx runs from 1 to 99 and yy from 1 to 9, which is not the last file of a video title and whose size is less than 2 ²⁰ - 2048 bytes (if any such File exists), and which ends close to the sector LSN = Last_LSN / 2?
• 216: end.

• 300: Start
• 301: Suche nach der Grenze zwischen Lead Out- und Daten-Bereich von Schicht 1.
• 302: End_PSN_Schicht_1 = 25 Bits niedrigster Wertigkeit von dem ID des gerade gefundenen Datenbereich-Sektors von Schicht 1;
• 303: Lies Sektor PSN = End_PSN_Schicht_1
• 304: identifiziere die ersten 16 Bytes der Haupt-Daten dieses Sektors diesen Sektor als einen Anker-Volumen-Deskriptor-Zeiger AVDP mit Tag = 2 (Tag ist ein Deskriptor-Typ-Indikator) ?
• 305: Der AVDP könnte beschädigt sein; Versuche den mittleren Bereich über das Dateisystem zu lokalisieren.
• 306: End_PSN_Schicht_0 = (Tag-Ort von dem Deskriptor-Tag des AVDP) – (End_PSN_Schicht_1 – 1000000h) + Start_PSN_Schicht_0 – 2)/2; Start_PSN_Schicht_1 = 1FFFFFFh – End_PSN_Schicht_0
• 307: Führe die Funktion aus „finde letzte LSN über Partitionsgröße"
• 308: untersuche die Strom-Dateien VTS_xx_yy.VOB, worin xx von 1 bis 99 und yy von 1 bis 9 läuft; suche nach einer VTS_xx_yy-VOB-Datei, die nicht die letzte Datei eines Videotitels ist, und deren größe beträchtlich kleiner als 2²⁰ – 2048 Bytes ist (wenn eine solche Datei vorhanden ist), und deren letzter Sektor so nahe wie möglich bei LSN = letzte_LSN/2 ist.
• 309: Gibt es eine solche Datei ?
• 310: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + letzte LSN der festgestellten VTS_xx_yy.VOB-Datei;setze die 8 LSBs von End_PSN_Schicht_0 auf 1; Start_PSN_Schicht_1 = 1FFFFFFh – End_PSN_Schicht_0.
• 311: Finde den Ort, oder LSN, der letzten VTS_xx_0.BUP-Datei der Platte über das Dateisystem, worin xx von 1 bis 99 läuft; berechne die Start-PSN dieser Datei: Start_PSN_letzter_BUP = LSN der letzten VTS_xx_0-BUP-Datei + Start_PSN_Schicht_0 + Start_PSN_Schicht_1 – End_PSN_Schicht_0 – 1;springe zum Sektor PSN = Start_PSN_letzter_BUP und lies diesen Sektor.
• 312: Ist dieser Sektor eine Video-Titelgruppen-Informations-Management-Tabelle VTSI_MAT ?
• 313: Suche in den Sektoren rund um die angenommene PSN nach der VTSI-MAT.
• 314: War Suche nach VTSI_MAT erfolgreich ?
• 315: End_PSN_Schicht_0 = Start_PSN der festgestellten VTS_xx_0.BUP-Datei – Start_PSN_Schicht_0 – Start_PSN_Schicht_1 + End_PSN_Schicht_0 + 1; Start_PSN_Schicht_1 = 1FFFFFFh – End_PSN_Schicht_0
• 316: Lies die VTSI_MATs der Dateien VTS_xx_0-IFO und VTS_xx_0.BUP, sie müssen sich unmittelbar vor der ersten und unmittelbar nach der letzten „.VOB"-Datei dieses Titels befinden.
• 317: Sind beide VTSI_MATs gleich ?
• 318: Start_PSN_Schicht_0 und End_PSN_Schicht_1 sind richtig.
• 319: Start_PSN_Schicht_0 und End_PSN_Schicht_1 sind falsch.
• 320: Gibt es eine andere Datei VTS_xx_yy.VOB, worin xx von 1 bis 99 und yy von 1 bis 9 läuft, die nicht die letzte Datei eines Videotitels ist, und deren Größe kleiner als 2²⁰ – 2048 Bytes ist (wenn eine solche Datei vorhanden ist), und die nahe bei dem Sektor LSN = letzte_LSN/2 endet ?
• 321: Ende

step 85 in 6 has the function name "find the main variables for the plate with opposite track path" and contains the others in 10 illustrated steps.

• 300: Start
• 301: Search for the boundary between Lead Out and Data area of Layer 1 ,
• 302: End_PSN_Layer_1 = 25 bits lowest Value of the ID of the just found data area sector of layer 1 ;
• 303: Read sector PSN = End_PSN_Layer_1
• 304: do the first 16 bytes of the main data of this sector identify this sector as an anchor volume descriptor pointer AVDP with tag = 2 (tag is a descriptor type indicator)?
• 305: The AVDP could be corrupted; Attempt to locate the middle area via the file system.
• 306: End_PSN_Layer_0 = (Tag Location of the AVDP Descriptor Tag) - (End_PSN_Layer_1 - 1000000h) + Start_PSN_Layer_0 - 2) / 2; Start_PSN_Layer_1 = 1FFFFFF H - End_PSN_Layer_0
• 307: Execute the function "find last LSN about partition size"
• 308: examine the stream files VTS_xx_yy.VOB, where xx runs from 1 to 99 and yy from 1 to 9; search for a VTS_xx_yy VOB file that is not the last file of a video title, and whose size is considerably less than 2 ²⁰ - 2048 bytes (if such a file exists), and its last sector as close as possible to LSN = Last_LSN / 2 is.
• 309: Is there such a file?
• 310: End_PSN_Layer_0 = Start_PSN_Layer_0 + Last LSN of the detected VTS_xx_yy.VOB file; set the 8 LSBs from End_PSN_Layer_0 to 1; Start_PSN_Layer_1 = 1FFFFFF H - End_PSN_Layer_0.
• 311: Find the location, or LSN, of the last VTS_xx_0.BUP file of the disk through the file system, where xx runs from 1 to 99; calculate the start PSN of this file: Start_PSN_last_BUP = LSN of the last VTS_xx_0 BUP file + Start_PSN_Schicht_0 + Start_PSN_Schicht_1 - End_PSN_Schicht_0 - 1; jump to sector PSN = Start_PSN_last_BUP and read this sector.
• 312: Is this sector a video title group information management table VTSI_MAT?
• 313: Search in the sectors around the assumed PSN after the VTSI-MAT.
• 314: Was searching for VTSI_MAT successful?
• 315: End_PSN_Schicht_0 = Start_PSN of the detected VTS_xx_0.BUP file - Start_PSN_Schicht_0 - Start_PSN_Schicht_1 + End_PSN_Schicht_0 + 1; Start_PSN_Layer_1 = 1FFFFFF H - End_PSN_Layer_0
• 316: Read the VTSI_MATs of the files VTS_xx_0-IFO and VTS_xx_0.BUP, they must be immediately before the first and immediately after the last ".VOB" file of this title.
• 317: Are both VTSI_MATs the same?
• 318: Start_PSN_Layer_0 and End_PSN_Layer_1 are correct.
• 319: Start_PSN_Layer_0 and End_PSN_Layer_1 are wrong.
• 320: Is there another file VTS_xx_yy.VOB, where xx runs from 1 to 99 and yy from 1 to 9, which is not the last file of a video title and whose size is less than 2 ²⁰ - 2048 bytes (if such a file is present), and which ends near the sector LSN = Last_LSN / 2?
• 321: end

Alternative fast processing steps to search for critical main variables

If the fast processing steps of searching described above failing critical main variables may require alternative processing steps accomplished to derive the most significant major variables, in particular End_PSN_Layer_0 for one Plate with parallel track path and End_PSN_Layer_0 or Start_PSN_Layer_1 for one Plate with opposite track path.

• 400: suche innerhalb des Dateisystems nach Dateisystem-Deskriptoren UDF, z. B. Datei-Eingabe-Deskriptoren, unmittelbar nach der Mitte des LSN-Bereiches der gesamten Platte. Diese Deskriptoren befinden sich wahrscheinlich in Schicht 1 unmittelbar nach dem Lead In.
• 401: Bewerte die PSN dieser Deskriptoren und springe zu einer PSN unmittelbar vor solch einer bewerteten PSN.
• 402: Suche nach diesen UDF-Deskriptoren. Die Identifikation kann durch Analysieren der ersten 16 Bytes jedes gelesenen Sektors ausgeführt werden. Die ersten 16 Bytes der UDF-Deskriptoren enthalten den Deskriptor-Tag, der charakteristische Informationen über diesen Deskriptor liefert. Daher kann ein UDF-Deskriptor leicht erkannt werden.
• 403: Der Tag-Ort enthält einen logischen Sektor-Ort von sich selbst. Der Tag-Ort einiger Deskriptoren wird relativ zu dem Start der Partition gezählt (Datei-Deskriptoren wie Datei-Eingabe-Deskriptoren). Einige Tag-Orte sind identisch mit LSN (Volumen-Deskriptoren, z. B. Anker-Volumen-Deskriptor-Zeiger). Der Tag-Ort dient zur Neuberechnung von End_PSN_Schicht_0
• 404: Erhalte die Start_LSN_ der UDF-Partition aus dem Partitions-Deskriptor.
• 405: Tag-Ort eines Daten-Deskriptors gefunden: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag-Ort + Start_LSN der UDF-Partition PSN des Deskriptors – 1
• 406: Tag-Ort eines Volumen-Deskriptors gefunden: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag-Ort – PSN des Deskriptors – 1

To get End_PSN_Layer_0 for parallel track plates:

• 400: search within the file system for file system descriptors UDF, z. For example, file input descriptors immediately after the middle of the LSN area of the entire disk. These descriptors are probably in layer 1 immediately after the lead in.
• 401: Evaluate the PSN of these descriptors and jump to a PSN immediately before such a rated PSN.
• 402: Search for these UDF descriptors. The identification can be carried out by analyzing the first 16 bytes of each read sector. The first 16 bytes of the UDF descriptors contain the descriptor tag which provides characteristic information about this descriptor fert. Therefore, a UDF descriptor can be easily recognized.
• 403: The tag location contains a logical sector location of itself. The tag location of some descriptors is counted relative to the start of the partition (file descriptors such as file input descriptors). Some tag locations are identical to LSN (volume descriptors, eg anchor volume descriptor pointer). The tag location is used to recalculate End_PSN_Layer_0
• 404: Get the Start_LSN_ of the UDF partition from the partition descriptor.
• 405: Tag location of a data descriptor found: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag Location + Start_LSN of the UDF partition PSN of the descriptor - 1
• 406: Tag location of a volume descriptor found: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag Location - PSN of the Descriptor - 1

• 450: Suche innerhalb des Dateisystems nach Dateisystem-Deskriptoren UDF, z. B. Datei-Eingabe-Deskriptoren, unmittel bar vor dem Ende des LSN-Bereichs der gesamten Platte. Diese Deskriptoren befinden sich wahrscheinlich in Schicht 1 unmittelbar nach dem Lead In.
• 451: Bewerte die PSN dieser Deskriptoren und springe zu einer PSN unmittelbar vor solch einer bewerteten PSN.
• 452: Suche nach diesen UDF-Deskriptoren. Die Identifikation kann durch Analysieren der ersten 16 Bytes jedes gelesenen Sektors ausgeführt werden. Die ersten 16 Bytes der UDF-Deskriptoren enthalten den Deskriptor-Tag, der charakteristische Informationen über diesen Deskriptor liefert. Daher kann ein UDF-Deskriptor leicht erkannt werden.
• 453: Der Tag-Ort enthält einen logischen Sektor-Ort von sich selbst. Der Tag-Ort einiger Deskriptoren wird relativ zu dem Start der Partition gezählt. (Datei-Deskriptoren wie Datei-Eingabe-Deskriptoren). Einige Tag-Orte sind identisch mit LSN (Volumen-Deskriptoren, z. B. Anker-Volumen-Deskriptor-Zeiger). Der Tag-Ort dient zur Neuberechnung von End_PSN_Schicht_0 und Start_PSN_Schicht_1.
• 454: Erhalte die Start_LSN der UDF-Partition aus dem Partitions-Deskriptor.
• 455: Tag-Ort eines Datei-Deskriptors gefunden: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag-Ort + Start_LSN der UDF-Partition – PSN des Deskriptors – 1
• 456: Tag-Ort eines Volumen-Deskriptors gefunden: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag-Ort – PSN des Deskriptors – 1
• 457: Start_PSN_Schicht_1 = 1FFFFFFh – End_PSN_Schicht_0

To get End_PSN_Layer_0 and Start_PSN_Layer_1 for plates with opposite lane:

• 450: search within the file system for file system descriptors UDF, e.g. File input descriptors, immediately before the end of the LSN area of the entire disk. These descriptors are probably in layer 1 immediately after the lead in.
• 451: Evaluate the PSN of these descriptors and jump to a PSN immediately before such a rated PSN.
• 452: Search for these UDF descriptors. The identification can be carried out by analyzing the first 16 bytes of each read sector. The first 16 bytes of the UDF descriptors contain the descriptor tag which provides characteristic information about this descriptor. Therefore, a UDF descriptor can be easily recognized.
• 453: The tag location contains a logical sector location of itself. The tag location of some descriptors is counted relative to the start of the partition. (File descriptors such as file input descriptors). Some tag locations are identical to LSN (volume descriptors, eg anchor volume descriptor pointer). The tag location is used to recalculate End_PSN_Schicht_0 and Start_PSN_Schicht_1.
• 454: Get the Start_LSN of the UDF partition from the partition descriptor.
• 455: Tag location of a file descriptor found: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag Location + Start_LSN of the UDF partition - PSN of the descriptor - 1
• 456: Tag location of a volume descriptor found: End_PSN_Schicht_0 = Start_PSN_Schicht_0 + Start_PSN_Schicht_1 + Tag Location - PSN of the Descriptor - 1
• 457: Start_PSN_Layer_1 = 1FFFFFF H - End_PSN_Layer_0

Of the Location of special DVD video files can also be analogous be used, for. B. files VTS_xx_0.IFO, where xx from 1 to 99 is running. These Files can be recognized by a method described in EP-A-1014372 the applicant is described. A comparison of the PSN of the detected VTS_xx_0.IFO file with its location specified by the file system leads to the calculation of End_PSN_Layer_0.

11 shows an optical disk D, which is driven by a motor M, and from which data are read by means of a scanner P. This data is supplied to a track buffer TB. The read data is stored in TB to compensate for different instantaneous or short term data rates. The corresponding sub-data streams of the data stream stored in the buffer are passed from TB to an associated decoder bit buffer. In this case, for example, a video, audio, sub-picture and / or data decoder DAR may be involved. The video decoder VID may be an MPEG video decoder. The audio decoder AUD may be an MPEG or AC3 audio decoder. Instead of a data decoder, it is also possible to use an output interface.

M, P, TB, VID, AUD and DAT are controlled by control means CTRL. These control means CTRL control the radial position of the scanner P and the speed of the motor M, evaluate the required read Data to run through the execution of described functional processing steps the above-mentioned main variables to determine.

The invention may also be used for other types of storage media having a first data area or data portion corresponding to the Lead In storing the main variables or main parameter values and having a second data area or data portion for others have data.

Claims (10)

Method for determining a main parameter value (End_PSN_Layer_0) of a storage medium (D) required for playing the storage medium, the storage medium comprising: - a plurality of physical data sectors; - multiple logical data sectors that are different from the physical data sectors; An lead-in area containing the main parameter value; Another data area different from the lead-in area and containing not the main parameter value but other data, characterized in that the main parameter value is an end-physical sector number (End_PSN_Layer_0) for the storage medium and that the main Parameter value is determined by reading and evaluating data from the other data area without reading the main parameter value from the lead-in area. The method of claim 1, wherein the storage medium (D) is a DVD disc, for. A read-only DVD or a DVD-Video disc. Method according to claim 1 or 2, wherein a physical Start sector number (Start_PSN_Layer_0) for the storage medium and, if necessary a type (disk type) of the storage medium further main parameter values are. The method of claim 1 or 2, wherein the storage medium (D) contains at least two data layers, each of which has a specific lead-in area (Lead in) is assigned. The method of claim 4, wherein the storage medium (D) at least one DVD read-only disc side with opposite Spurweg and the main parameter value is an end-physical Sector number (End_PSN_Layer_0) for the first of the at least two data layers of the disk, or a start-physical sector number (Start_PSN_Schicht_1) for the second of the at least two data layers of the disk. The method of claim 4, wherein the storage medium (D) at least one parallel track DVD read only disc side and the main parameter value is an end-physical sector number (End_PSN_Layer_0) for the first of the at least two data layers of the disk, and a another main parameter value a start-physical sector number (Start_PSN_Schicht_1) for the second of the at least two data layers of the disk. Method according to claim 5 or 6, wherein the main parameter value and the other main parameter values are a start-physical sector number (Start_PSN_Layer_0) and the end-physical sector number (End_PSN_Layer_0) for the first of the at least two data layers of the disk, and one or the start-physical sector number (Start_PSN_Schicht_1) and an end physical sector number (End_PSN_Layer_1) for the second the at least two data layers of the disk and optionally one Type (plate type) of the plate included. Method according to one of Claims 1 to 7, in which the storage medium (D) is a DVD-video disc and in which the following other data area data are used to determine the main parameter or the disc type: - characteristic file System data at the beginning of the shift 0 - DVD-video-specific data located at the beginning of the shift 0 are located; - sector IDs; - if shift 1 There is DVD-video-specific data that resides at the inner radius of the layer 1 are located; If there is a plate with opposite track path, the structure of DVD-video specific data that is at the outer radius of the layers 0 and 1 are located. Device for determining a main parameter value (End_PSN_Layer_0) of a data disk (D) required for playing back the data disk, the data disk containing: - a plurality of physical data sectors; - multiple logical data sectors that are different from the physical data sectors; An lead-in area containing the main parameter value; Another data area different from the lead-in area and containing not the main parameter value but other data, the device comprising: means (M) for driving the data disk (D); A scanning device (P) for reading data from the data disk; A buffer (TB); - means (CTRL) for controlling the drive means (M), the sampling arrangement (P) and the buffer (TB), characterized in that the apparatus comprises means for acquiring the main parameter value by reading and evaluating data from the other data area without reading the main parameter value from the lead-in area, the main parameter value being an end-physical sector number (End_PSN_Layer_0) for the storage medium is. Device according to Claim 9, in which the storage medium (D) is a DVD-video disc and in which the following other data area data are used to determine the main parameter or the main parameter or the disc type: System data at the beginning of shift 0 ; - DVD-video-specific data that is at the beginning of shift 0 are located; - sector IDs; - if shift 1 There is DVD-video-specific data that resides at the inner radius of the layer 1 are located; If there is a plate with opposite track path, the structure of DVD-video specific data that is at the outer radius of the layers 0 and 1 are located.